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Clinical, laboratory and imaging features of COVID-19: A systematic review and meta-analysis
Alfonso J. Rodriguez-Morales, Jaime A. Cardona-Ospina, Estefanía Gutiérrez-Ocampo, Rhuvi Villamizar-Peña, Yeimer Holguin-Rivera, Juan Pablo Escalera-Antezana, Lucia Elena Alvarado-Arnez, D. Katterine Bonilla-Aldana, Carlos Franco-Paredes, Andrés F. Henao-Martinez, Alberto Paniz-Mondolfi, Guillermo J. Lagos-Grisales, Eduardo Ramírez-Vallejo, Jose A. Suárez, Lysien I. Zambrano, WilmerE. Villamil-Gómez, Graciela J. Balbin-Ramon, Ali A. Rabaan, Harapan Harapan,Kuldeep Dhama, Hiroshi Nishiura, Hiromitsu Kataoka, Tauseef Ahmad, Ranjit Sah,On behalf of the Latin American Network of Coronavirus Disease 2019-COVID-19Research (LANCOVID-19)
PII: S1477-8939(20)30091-0
DOI: https://doi.org/10.1016/j.tmaid.2020.101623
Reference: TMAID 101623
To appear in: Travel Medicine and Infectious Disease
Received Date: 29 February 2020
Revised Date: 11 March 2020
Accepted Date: 11 March 2020
Please cite this article as: Rodriguez-Morales AJ, Cardona-Ospina JA, Gutiérrez-Ocampo Estefaní,Villamizar-Peña R, Holguin-Rivera Y, Escalera-Antezana JP, Alvarado-Arnez LE, Bonilla-Aldana DK,Franco-Paredes C, Henao-Martinez AndréF, Paniz-Mondolfi A, Lagos-Grisales GJ, Ramírez-VallejoE, Suárez JA, Zambrano LI, Villamil-Gómez WE, Balbin-Ramon GJ, Rabaan AA, Harapan H, DhamaK, Nishiura H, Kataoka H, Ahmad T, Sah R, On behalf of the Latin American Network of CoronavirusDisease 2019-COVID-19 Research (LANCOVID-19), Clinical, laboratory and imaging features ofCOVID-19: A systematic review and meta-analysis, Travel Medicine and Infectious Disease (2020), doi:https://doi.org/10.1016/j.tmaid.2020.101623.
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© 2020 Published by Elsevier Ltd.
Credit Author Statement
AJRM and JACO conceptualization; Data curation; Formal analysis; Funding acquisition; Investigation; Methodology;
Project administration; Resources; Software; Supervision; Validation; Visualization; Writing - original draft; Writing -
review & editing. EGO, RV, YHR Data curation; Formal analysis; Funding acquisition; Investigation; Methodology;
Project administration; Resources; Software; Supervision; Validation; Visualization; Writing - original draft; Writing -
review & editing. DKBA Supervision; Validation; Visualization; Writing - original draft; Writing - review & editing. All
authors Writing - review & editing.
1
Systematic Review
Clinical, Laboratory and Imaging Features of COVID-19: A systematic review and meta-analysis
Alfonso J. Rodriguez-Morales,1,2,3,4,5,a,* Jaime A. Cardona-Ospina,1,2,3,4,6,7,8,a Estefanía Gutiérrez-Ocampo,1 Rhuvi
Villamizar-Peña,1 Yeimer Holguin-Rivera,1 Juan Pablo Escalera-Antezana,9,10 Lucia Elena Alvarado-Arnez,9 D.
Katterine Bonilla-Aldana,1,3,11 Carlos Franco-Paredes,4,12,13 Andrés F. Henao-Martinez,12 Alberto Paniz-Mondolfi,4,
14,15,16,17 Guillermo J. Lagos-Grisales,1 Eduardo Ramírez-Vallejo,1 Jose A. Suárez,3,18 Lysien I. Zambrano,19 Wilmer
E. Villamil-Gómez,3,4,20,21 Graciela J. Balbin-Ramon,5,22 Ali A. Rabaan,23 Harapan Harapan,24,25,26 Kuldeep Dhama,27
Hiroshi Nishiura, 28 Hiromitsu Kataoka,29 Tauseef Ahmad,30,31 Ranjit Sah.32 On behalf of the Latin American
Network of Coronavirus Disease 2019-COVID-19 Research (LANCOVID-19) (www.lancovid.org).
1Public Health and Infection Research Group, Faculty of Health Sciences, Universidad Tecnológica de Pereira, Pereira, Risaralda,
Colombia.
2Grupo de Investigación Biomedicina, Faculty of Medicine, Fundación Universitaria Autónoma de las Américas, Pereira, Risaralda,
Colombia.
3Comittee on Tropical Medicine, Zoonoses and Travel Medicina, Asociación Colombiana de Infectología, Bogotá, DC, Colombia.
4Committe on Travel Medicine, Pan-American Association of Infectious Diseases (API), Pereira, Risaralda, Colombia.
5Master in Clinical Epidemiology and Biostatistics, Universidad Cientifica del Sur, Lima, Peru.
6Grupo de Investigación Infección e Inmunidad, Faculty of Health Sciences, Universidad Tecnológica de Pereira, Pereira, Risaralda,
Colombia.
7Semillero de Investigación en Infecciones Emergentes y Medicina Tropical, Faculty of Medicine, Fundación Universitaria Autónoma
de las Américas, Pereira, Risaralda, Colombia.
8Emerging Infectious Diseases and Tropical Medicine Research Group, Instituto para la Investigación en Ciencias Biomédicas – Sci-
Help, Pereira, Risaralda, Colombia.
9Universidad Franz Tamayo/UNIFRANZ, Cochabamba, Bolivia.
10National Responsible for Telehealth Program, Ministry of Health, La Paz, Bolivia.
11Incubator in Zoonosis (SIZOO), Biodiversity and Ecosystem Conservation Research Group (BIOECOS), Fundación Universitaria
Autónoma de las Américas, Sede Pereira, Pereira, Risaralda, Colombia.
12Division of Infectious Diseases, Department of Medicine, University of Colorado Anschutz Medical Center, Aurora, CO, USA.
13Hospital Infantil de México Federico Gómez, México City, Mexico.
14Laboratory of Medical Microbiology, Department of Pathology, Molecular and Cell-based Medicine, The Mount Sinai Hospital-Icahn
School of Medicine at Mount Sinai, New York, USA.
15Laboratorio de Señalización Celular y Bioquímica de Parásitos, Instituto de Estudios Avanzados (IDEA), Caracas, Caracas,
Venezuela.
16Academia Nacional de Medicina, Caracas, Venezuela.
17Instituto de Investigaciones Biomedicas IDB / Incubadora Venez/olana de la Ciencia, Cabudare, Edo. Lara, Venezuela.
2
18Investigador SNI Senacyt Panamá, Clinical Research Deparment, Instituto Conmemorativo Gorgas de Estudios de la Salud, Panamá
City, Panama.
19Departments of Physiological and Morphological Sciences, School of Medical, Sciences, Universidad Nacional Autónoma de
Honduras (UNAH), Tegucigalpa, Honduras.
20Infectious Diseases and Infection Control Research Group, Hospital Universitario de Sincelejo, Sincelejo, Sucre, Colombia.
21Programa del Doctorado de Medicina Tropical, SUE Caribe, Universidad del Atlántico, Barranquilla, Colombia.
22Hospital de Emergencias Jose Casimiro Ulloa, Lima, Peru.
23Molecular Diagnostic Laboratory, Johns Hopkins Aramco Healthcare, Dhahran, Saudi Arabia.
24Medical Research Unit, School of Medicine, Universitas Syiah Kuala, Banda Aceh, Indonesia.
25Tropical Disease Centre, School of Medicine, Universitas Syiah Kuala, Banda Aceh, Indonesia.
26Department of Microbiology, School of Medicine, Universitas Syiah Kuala, Banda Aceh, Indonesia.
27Division of Pathology, ICAR-Indian Veterinary Research Institute, Izatnagar 243 122, Bareilly, Uttar Pradesh, India.
28Graduate School of Medicine, Hokkaido University, Kita 15 Jo Nishi 7 Chome, Kita-ku, Sapporo-shi, Hokkaido 060-8638, Japan.
29Hamamatsu University School of Medicine, Internal Medicine 3rd Division, Department of Cardiology, Hamamatsu, Shizuoka, Japan.
30Department of Epidemiology and Health Statistics, School of Public Health, Southeast University, Nanjing 210009, China.
31Key Laboratory of Environmental Medicine Engineering, Ministry of Education, School of Public Health, Southeast University,
Nanjing, China.
32Department of Microbiology, Tribhuvan University Teaching Hospital, Institute of Medicine, Kathmandu, Nepal.
aBoth authors contributed equally. Order was decided by seniority.
*Corresponding Author. Email: arodriguezm@utp.edu.co
Words count: 3,811 | Abstract: 249 | References: 75 | Tables: 7 | Figures: 1 | Supplemental Material: Figures: 2, Tables: 1.
Running Head: Clinical Features of Coronavirus Disease 2019 – Systematic Review
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Abstract
Introduction: An epidemic of Coronavirus Disease 2019 (COVID-19) began in December 2019 in China leading to a
Public Health Emergency of International Concern (PHEIC). Clinical, laboratory, and imaging features have been partially
characterized in some observational studies. No systematic reviews on COVID-19 have been published to date.
Methods: We performed a systematic literature review with meta-analysis, using three databases to assess clinical,
laboratory, imaging features, and outcomes of COVID-19 confirmed cases. Observational studies and also case reports,
were included, and analyzed separately. We performed a random-effects model meta-analysis to calculate the pooled
prevalence and 95% confidence interval (95%CI).
Results: 660 articles were retrieved for the time frame (1/1/2020-2/23/2020). After screening, 27 articles were selected for
full-text assessment, 19 being finally included for qualitative and quantitative analyses. Additionally, 39 case report articles
were included and analyzed separately. For 656 patients, fever (88.7%, 95%CI 84.5-92.9%), cough (57.6%, 40.8-74.4%)
and dyspnea (45.6%, 10.9-80.4%) were the most prevalent manifestations. Among the patients, 20.3% (95%CI 10.0-30.6%)
required intensive care unit (ICU), 32.8% presented with acute respiratory distress syndrome (ARDS) (95%CI 13.7-51.8),
6.2% (95%CI 3.1-9.3) with shock. Some 13.9% (95%CI 6.2-21.5%) of hospitalized patients had fatal outcomes (case
fatality rate, CFR).
Conclusion: COVID-19 brings a huge burden to healthcare facilities, especially in patients with comorbidities. ICU was
required for approximately 20% of polymorbid, COVID-19 infected patients and hospitalization was associated with a CFR
of over 13%. As this virus spreads globally, countries need to urgently prepare human resources, infrastructure and
facilities to treat severe COVID-19.
Keywords: Coronavirus Disease 2019; SARS-CoV-2; clinical features; laboratory; outcomes; epidemic.
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Introduction
Rationale
The Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2), formerly known as the 2019 novel Coronavirus
(2019nCoV), is a newly emerging zoonotic agent that appeared in December 2019 and causes the Coronavirus Disease 2019
(COVID-19) [1]. This pathogen results in a syndrome leading in some cases to a critical care respiratory condition, that
requires specialized management at intensive care units (ICU) in many of them [2-7]. The SARS-CoV-2, taxonomically, is
currently part of the species of the SARS-related coronaviruses that belong to the subgenus Sarbecovirus. Together with the
subgenuses Embecovirus, Hibecovirus, Merbecovirus, and Nobecovirus, that are part of the genus Betacoronavirus (order
Nidovirales; suborder Cornidovirineae; family Coronaviridae; subfamily Coronavirinae) [8-14].
Other Betacoronaviruses before have caused epidemics over the last two decades in Asia, as is the case of SARS-CoV in
2002-2003 in China [10, 15, 16], and later with the Middle East Respiratory Syndrome (MERS-CoV) in 2012-2013 in Saudi
Arabia [17-20]. As expected, several similarities and differences in the epidemiology, clinical features, and management of
SARS, MERS, and COVID have been identified [3-5, 20-23]. These are enveloped positive-strand RNA viruses isolated
from bats that share sequence homology with isolates from humans, suggesting bats as natural hosts and reservoirs [9, 24-
27]. Although the clinical picture of SARS, MERS, and COVID-19 seems to be similar, differences were noted [4, 5, 21,
28] are apparent since early reports. A full clinical characterization of this disease, as well as its laboratory and image
characteristics, is required.
Although only two months have elapsed since the emergence of COVID-19, some studies and case reports have been
already published in major international scientific and medical journals, from China and other countries with travel- and
non-travel-related cases [7, 13, 29, 30]. Many of these reports have started to answer clinical questions, including evolution
and outcomes, as well as potential risk factors, and clinical, laboratory and image findings; however, a systematic review to
consolidate what has been learned from each study or reported case is to-date missing. Although systematic reviews and
meta-analyses usually include randomized clinical trials (RCTs) and aim to provide a more precise estimate of the effect of
a treatment or risk factor for disease, also have been extensively used, especially during the last decades, to synthesized
observational studies [31-33]. In many situations, RCTs are not feasible or available, and only data from observational
studies are accessible [33]. This is the case for the clinical, laboratory, and image features of COVID-19.
Objectives
• To summarize the clinical, laboratory, and image features of COVID-19 reported in currently available observational
studies.
• To examine the outcome of COVID-19 cases, including risk factors, the proportion of patients requiring ICU and those
with fatal outcomes.
• To assess the prevalence of comorbidities among COVID-19 confirmed cases.
5
Methods
Protocol and registration
This protocol follows the recommendations established by the Preferred Reporting Items for Systematic Reviews and Meta-
Analyses (PRISMA) statement [34], and it has been reported in the International Prospective Register of Systematic
Reviews (PROSPERO) database (ID 170643).
Eligibility criteria
We included published peer-reviewed articles that reported cases with demographical, clinical, laboratory, and image
features of real-time reverse transcriptase polymerase chain reaction (rRT-PCR) confirmed SARS-CoV-2 infection. For
assessing clinical, laboratory and imaging characteristics eligible study designs were case-control, cohort studies, case
reports, and case series. For assessing risk factors and outcomes only observational studies were included. Article language
limit was not set, and we included publications from January 1, 2020 until February 23rd, 2020. Review articles, opinion
articles and letters not presenting original data were excluded, as well as studies reporting cases with incomplete
information.
Information sources and Search Strategy
We conducted a systematic review using Medline/PubMed, Scopus, and Web of Sciences. The search terms used: “Novel
coronavirus,” “Novel coronavirus 2019”, “2019 nCoV”, “COVID-19”, “Wuhan coronavirus,” “Wuhan pneumonia,” and
“SARS-CoV-2.” The searches were concluded by February 23, 2020, and four different researchers independently evaluated
search results.
Study Selection
The results of the initial search strategy were first screened by title and abstract. The full texts of relevant articles were
examined for inclusion and exclusion criteria (Figure 1). When an article reported duplicate information from the same
patient, the information of both reports was combined in order to obtain complete data, but only counted as a single case.
Observational studies that reported the proportion of symptoms, laboratory characteristics and risk factors were included for
quantitative synthesis (meta-analysis). Case reports were not included for the meta-analysis, as they do not have a
denominator for any variables, but descriptive statistics were applied to them, to summarize their findings.
Data collection process and data items:
6
Data extraction forms including information on the type of publication, the publishing institution, country, year and date of
publication, the number of reported cases, of cases at ICU, age, sex, comorbidities, clinical features (e.g., fever, cough),
laboratory findings (e.g., white blood cell counts [WBC], biochemistry), imaging (e.g., chest X-ray), complications (e.g.,
acute respiratory distress syndrome, ARDS), outcome (e.g., death) were filled independently by four investigators. A fifth
researcher checked the article list and data extractions to ensure there were no duplicate articles or duplicate information of
the same patient and also resolved discrepancies about study inclusion.
Assessment of methodological quality and risk of bias:
For quality assessment, we used the Quality Appraisal of Case Series Studies Checklist of the IHE and specifically the
critical appraisal tool to assess the quality of cross-sectional studies (AXIS) [35, 36]. Publication bias was assessed using a
funnel-plot. A random-effects model was used to calculate the pooled prevalence and 95%CI, given variable degrees of data
heterogeneity, and given the inherent heterogeneity in any systematic review of studies from the published literature.
Egger’s test for publication bias was also performed.
Statistical approach
Unit discordance for variables was resolved by converting all units to a standard measurement for that variable. Percentages
and means ± standard deviation (SDs) were calculated to describe the distributions of categorical and continuous variables,
respectively. Since individual patient information was not available for all patients, we report weighted means and SDs. The
baseline data were analyzed using the Stata version 14.0, licensed for Universidad Tecnológica de Pereira.
The meta-analyses were performed using Stata, and the software OpenMeta[Analyst] [37] and Comprehensive Meta
Analysis ve.3.3® licensed for Universidad Tecnológica de Pereira, Colombia. Pooled prevalences and their 95% confidence
intervals (95% CIs) were used to summarize the weighted effect size for each study grouping variable using the binary
random-effects model (the weighting took into consideration the sample sizes of the individual studies), except for median
age, where a continuous random-effect model was applied (DerSimonian-Laird procedure) [38, 39].
Measures of heterogeneity, including Cochran’s Q statistic, the I2 index, and the tau-squared test, were estimated and
reported. We performed subgroup analyses by age groups (adults or children). And meta-analyses for each of the variables
of interest. Publication bias was assessed using a funnel-plot.
Results
Study Selection and Characteristics:
7
A total of 660 articles were retrieved using the search strategy, including 39 case reports. After screening by abstract and
title, 64 articles were selected for full-text assessment. Of these, six were excluded due to lack of information on molecular
diagnosis, and 58 were finally included for final qualitative analysis, 19 of them for quantitative meta-analysis and 39 case
reports for descriptive analysis (Figure 1). The main characteristics of the included studies are shown in Table 1.
Our review included 19 studies that were published between January 1, 2020, and February 21, 2020, most of them from
China (18) and one from Australia (Table 1), including a total of 2,874 patients, ranging from a case series of 9 [40] to a
cross-sectional study of 1,590 [41]. Although as of March 9, 2020, there have been more than 111,000 cases reported, these
have not been included and published in studies available in the literature. Most studies were cross-sectional (15), and four
were case series (Tables 1-5). We analyzed 42 variables for the meta-analyses (Table 6). Publication bias was assessed with
a funnel plot for the standard error by logit event, with no evidence of bias (Figure S1). Additionally, the Egger test
(P = 0.801) suggested that there was no notable evidence of publication bias.
Demographical characteristics and comorbidities:
The mean age of patients across 18 studies was 51.97 years old (95%CI 46.06-57.89), being male 55.9% (95%CI 51.6-
60.1%). Patients presented in 36.8% of cases with comorbidities (95%CI 24.7-48.9%), the most significant being
hypertension (18.6%, 95%CI 8.1-29.0%), cardiovascular disease (14.4%, 95%CI 5.7-23.1%), and diabetes (11.9%, 95%CI
9.1-14.6%), among others (Table 6) (Figure S2).
Clinical manifestations and laboratory findings:
Regarding the clinical manifestations, fever (88.7%, 95%CI 84.5-92.9%), cough (57.6%, 40.8-74.4%) and dyspnea (45.6%,
10.9-80.4%) were the most prevalent clinical manifestations (Table 6). Fever frequency was significantly higher in adults
compared to children (92.8%, 95%CI 89.4-96.2%; versus 43.9%, 95%CI 28.2-59.6%) (Figure S2).
With regard to laboratory findings, decreased albumin (75.8%, 95%CI 30.5-100.0%), high C-reactive protein (58.3%,
95%CI 21.8-94.7%), and high lactate dehydrogenase (LDH) (57.0%, 95%CI 38.0-76.0), lymphopenia (43.1%, 95%CI 18.9-
67.3), and high erythrocyte sedimentation rate (ESR) (41.8%, 95%CI 0.0-92.8), were the most prevalent laboratory results
(Table 6) (Figure S2).
Imaging, Complications, and Outcomes:
At the chest X-rays, the pneumonia compromise was predominantly bilateral (72.9%, 95%CI58.6-87.1), with image
findings ground-glass opacity in 68.5% (95%CI 51.8-85.2) (Table 6) (Figure S2) in those with X-ray results.
Among the patients, 20.3% (95%CI 10.0-30.6%) who required ICU, 32.8% presenting with ARDS (95%CI 13.7-51.8),
13.0% with acute cardiac injury (95%CI 4.1-21.9%), 7.9% with acute kidney injury (95%CI 1.8-14.0%), 6.2% (95%CI 3.1-
8
9.3%) with shock and 13.9% (95%CI 6.2-21.5%) had fatal outcomes (Table 6). RNAemia (detection of viral RNA in blood)
was reported 96.8% of the all patients (95%CI 94.9-98.7%) (Table 6) (Figure S2), and also in nasopharyngeal aspirates
(NPA).
Case reports:
We found 39 case report articles (Table S1, summarizing 126 cases of COVID-19. The mean age was 47.9 y-old (SD 22.2),
being male 69.01% of those with sex identified in the article (Table 7). From the total, 10.3% presented hypertension as
comorbidity, followed by other conditions. The more common clinical features were fever (77.0%), cough (55.6%), and
myalgia (31.0%), among others (Table 7). Regarding the laboratory findings, lymphopenia was the more frequent (23.8%),
followed by high C-reactive protein (22.2%) and high aspartate transaminase (AST) (7.9%). At the chest X-ray, 46%
presented ground-glass opacity, with a bilateral compromise in 39.7% of the patients. All the case reports had RNAaemia.
For the complications, 7.1% presented with ARDS, and 1.6% with secondary infections, among others. Most of the cases
described in these case reports were hospitalized (74.6%), with a fatality rate of 15.9% (Table 7).
Discussion
Over the last two months, more than 121,000 cases of a new infectious disease have been confirmed in China and other
countries in Asia, Europe, Africa, and the Americas [22, 23, 42-44]. The COVID-19 is an emerging condition that primarily
threatens the preparedness and biosecurity conditions of all countries on this planet [45]. Preparedness at different levels,
facing a new clinical disease, demands efforts in epidemiological, diagnostic, therapeutic, and preventive fields during a
potential pandemic [46], that threatens to spread to new territories (>115) and areas with the risk of epidemics.
Clinical, laboratory, image findings, as well as the factors associated with evolution of the disease and outcomes, constitute
critical knowledge that should be carefully studied when a new infectious disease emerges. Recently, in this context of the
COVID-19 outbreak, several questions have been raised, including what is the full spectrum of disease severity (which can
range from asymptomatic, to symptomatic-but-mild, to severe, to requiring hospitalization, to fatal)? [47]. In this systematic
review and random-effects meta-analysis, we tried to initially summarize clinical data on COVID-19 confirmed cases that
were published during the first weeks of the outbreak. We managed to analyze more than 780 patients for major clinical
manifestations and up to half of them for their associated significant laboratory findings. Our findings are robust in that we
used a random-effects meta-analysis model. This involves an assumption that the effects being estimated in the different
studies are not identical, but follow some distribution. For random-effects analyses, the pooled estimate and 95%CIs refer to
the center of the distribution of pooled prevalence but do not describe the width of the distribution. Often the pooled
estimate and its 95%CI are quoted in isolation as an alternative estimate of the quantity evaluated in a fixed-effect meta-
analysis, which is inappropriate. The 95%CI from a random-effects meta-analysis describes uncertainty in the location of
the mean of systematically different prevalence in the different studies [38, 39].
9
As expected from initial observations in China [4, 5, 11], COVID-19 patients presented predominantly with fever and
cough, which appears to be more frequent in adults than children, as well as dyspnea, and myalgia, among other clinical
features. This was consistently found not only in the studies meta-analyzed here but also in the case reports included in this
systematic review. Fever frequency is similar in SARS and MERS, but the cough frequency is higher in SARS and COVID-
19 than MERS (<50%) [28, 48, 49]. In SARS and MERS, diarrhea is reported in 20-25% of patients [50], here we found it
in less than 7%, at the studies (Table 6) and case reports (Table 7). Of note, in the case reports, myalgia was the third most
common reported symptom after fever and cough. Most patients required hospitalization, often attributed to the patient’s
comorbidities, as observed in a third of the cases. We found that approximately 20% of those hospitalized needed to be
admitted to ICU for critical management. Unlike SARS, with it is well-characterized two-stage clinical course of the
disease, COVID-19, still needs further definition [48]. The first week of the condition is also similar, coinciding with recent
data of the viral load during this stage [51]. However, case-control studies and cohort studies are necessary to define the
clinical evolution of disease better. A second stage, as occurs in SARS, is maybe also seen in COVID-19, with the lower
respiratory tract bilateral compromise, observed in more than 72% of the patients across nine studies with more than 500
patients, also experiencing a dry cough, and dyspnea [5, 48, 52] and with chest X-ray images of ground-glass opacity
frequently observed in two-thirds of patients – this is also seen in SARS [53].
The laboratory abnormalities predominantly found included hypoalbuminemia, elevated inflammatory markers, such as C-
reactive protein, LDH, and ESR, among others. Also, lymphopenia is consistently present in more than 40% of the patients
across eight studies with more than 500 patients. Data from the 2002-2003 outbreak indicate that SARS may be associated
with lymphopenia, leukopenia, and thrombocytopenia, elevated levels of LDH, alanine transaminase (ALT), AST, and
creatine kinase [54, 55], but also, and not significantly seen, nor consistently reported, in COVID-19 studies and cases, with
thrombocytopenia, mild hyponatremia, and hypokalemia. The frequency of lymphopenia found suggests that COVID-19
might act on lymphocytes, especially T lymphocytes, as does SARS-CoV, maybe including depletion of CD4 and CD8 cells
[4]. Virus particles spread through the respiratory mucosa, initially using the ACE2 receptor at ciliated bronchial epithelial
cells, and then infect other cells. This induces a cytokine storm in the body and generate a series of immune responses, that
cause changes in peripheral white blood cells and immune cells such as lymphocytes [56, 57].
With regard to complications and death, a third of patients presented with ARDS, but also, albeit in a lower frequency, acute
cardiac injury, acute kidney injury, and shock, eventually followed by multiple organ failure. Therefore, early identification
and timely treatment of critical cases are of crucial importance [4]. We observed a CFR of over 13% in 7 studies describing
632 hospitalized patients. In two studies in China (n=41, n=99), the case fatality rates were 15% [5] and 11% [4],
respectively. Crude surveillance data [42], indicated that till March 9, 2020, from 111,363 reported cases, 3,892 patients
have died (3.49%), with >89% of the deaths occurring in China (3,119). This differs from the CFR found in our systematic
review and may be explained by the fact that cases requiring medical attention in hospitals where patients were included the
selected studies consulted with a more advanced stage of disease leading to hospitalization. Even, from the crude
epidemiological data reported by the countries, some of them have reported a higher proportion of deaths, as is the case of
10
Australia (3.75%), China (3.86%), Italy (4.96%), Argentina (8.33%), and Iraq (10.0%). Thus, the CFR in different settings
needs further reassessment. More studies are needed to elucidate the risk factors for severe illness and death. This will
allow for the identification of groups most likely to have poor outcomes so that we can focus on prevention and treatment
efforts? [47].
After the development of this systematic review (SR), and even availability on a preprint server, online Feb. 25, 2020
(http://dx.doi.org/10.20944/preprints202002.0378.v1); a brief systematic review and meta-analysis, only addressing few
variables, such as fever, cough, muscle soreness or fatigue, ARDS, abnormal chest CT, patients in critical condition and
death of patients with COVID-19, was published (Feb. 28, 2020) [58]. This review was based on ten studies, using a
random effect model, as we did.
Comparing their findings [58] with ours, they found fever in 89.8% (95%CI 81.8-94.5%) of patients, this SR found 88.7%
(95%CI 84.5-92.9%), but we assessed differences, as mentioned above, between adults and children, and they did not. For
cough, based on the 95%CI, there were not significant differences too, between that SR and the current, 72.2% (95%CI
65.7-78.2%) versus 57.6% (95%CI 40.8-74.4%). For fatigue, there is a variation in frequency between both studies, 42.5%
(95%CI 21.3-65.2%) versus 29.4% (95%CI 19.8-39.0%). Sun et al did not assess other clinical manifestations [58], we were
able to do it for eight of the studies included in this systematic review. Both reviews are clear and consistent in that more
than 80% of the patients presented with fever, more than half with cough, and more than a third with fatigue. That SR did
not assess any laboratory findings, but evaluated the frequency of patients presenting ADRS which was found to be 14.8%
(95%CI 4.6-29.6%), which was also consistent with our study, 32.8% (95%CI 13.7-51.8%), which although higher, was not
significantly so. For patients admitted to ICU, there were also small differences. Sun et al found 18.1% (95%CI 12.7-
24.3%), however, we identified that 20.3% required intensive critical care (95%CI 10.0-30.6%). The major difference
between both studies was in the last variable assessed i.e. the case fatality rate. Sun et al. report 4.3% (95%CI 2.7-6.1%)
and we report a rate of 13.9% (95%CI 6.2-21.5%), which is significantly higher. Finally, Sun et al only included studies, but
not case reports, as we did, which provided additional consistent findings of the clinical, laboratory, imaging and evolution
characteristics of patients with confirmed COVID-19.
Our results showed that there is still a need for more comprehensive clinical studies, including short and long -term follow-
up cohort assessments. More studies from outside China, where there are more than 100 patients diagnosed with COVID-
19, as is the case of South Korea, Italy, and Japan [59, 60], will contribute to the growing volume of data, in addition to the
growing number of studies appearing from China. Even more, the situation with the cruise ship Diamond Princess, docked
in Yokohama, Japan, with 3,711 passengers, approximately 20% of the infected, with 7 deaths, is also a valuable chance to
better characterize COVID-19. Clinical evidence synthesized in this review is mainly derived from China, although for case
reports, ten of the thirty-two countries with confirmed cases [7, 12, 29, 30], have published some of them (Table 7). Further
clinical data is crucial to elucidate the clinical spectrum of the disease. The clinical experience stemming from countries
now dealing with an ever increasing number of cases such as Italy, [61], Singapore, Hong Kong, Nepal [7], Iran, and
11
Malaysia in the form of case reports, case series, or large observational studies will be most important. Up to now,
regardless whether of report type (cross-sectional studies or case reports) the clinical findings are consistent, but more data
are needed to define the risk factors for admission in ICU and for fatal outcomes. However, data suggest that older age and
comorbidities play a vital role in influencing severe disease and negative clinical outcomes. These data would be useful to
guide patient risk groups management in the current epidemic, especially in those countries about to receive cases, as is the
situation in Latin America. COVID-19 cases have been confirmed in Brazil, Mexico, Ecuador, Argentina, Chile, Peru,
Costa Rica, Dominican Republic, Paraguay, Colombia, Panama, Honduras, and Bolivia, among others, as of the time of
writing (March 11, 2020) [62]. In these and other resource-constrained settings, e.g. Africa, supplies chains, including those
for drugs, masks and personal protection equipment, will be challenged.
The results of this systematic review highlight the clinical, laboratory, and imaging findings that may assist clinicians
anywhere in the globe in suspecting the possibility of COVID-19 infection in those with recent travel to areas with ongoing
transmission or among contacts of confirmed cases. Early recognition of cases will allow clinicians to ensure adequate
clinical monitoring, institution of supportive interventions, and preventing further transmission by implementing of
infection control measures [29, 56, 63]. There is a need for prospective studies to evaluate the epidemiology, pathogenesis,
duration of viral shedding, and the clinical spectrum of disease associated with this emerging viral infection [29, 56, 63].
To effectively protect populations and healthcare workers in the face of arrival and spreading of this emerging viral
pathogen, constant evaluation of available evidence is essential to guide clinical suspicion, diagnosis, management and
mitigation of transmission of COVID-19.
Limitations
This review has several limitations. Few studies are available for inclusion. Most are from China. It would be better to
include as many studies with a broad geographic scope, to get a more comprehensive understanding of COVID19. More
detailed patient information, particularly regarding clinical outcomes, was unavailable in most studies at the time of
analyses; however, the data in this review permit a first synthesis of the clinical and laboratory characteristics of COVID-19.
Our systematic review and meta analysis found a CFR of over 13%. As we discussed earlier, the differences between the
crude fatality rate (<3.5%) and that found among hospitalized patients in the selected studies included here may be
explained by the fact that cases requiring medical attention in hospitals consulted with a more advanced stage of disease,.
Conclusions
Infection with COVID-19 is associated with significant morbidity especially in patients with chronical medical conditions.
At least one fifth of cases require supportive care in medical intensive care units. Despite the implementation of optimal
supportive interventions, case fatality rate among hospitalized patients is more than 10 percent. Similar to other viral
12
respiratory pathogens, COVID-19 presents in the majority of cases with a rapidly progressive course of fever, cough and
dyspnea. Important distinguishing factors are leukopenia and the rapid progression to ARDS. Eliciting a history of recent
travel to areas with ongoing outbreaks of this emerging pathogen or contact with a confirmed case of COVID-19, should
prompt clinicians to initiate isolation precautions and obtain laboratory confirmation. Additional research is needed to
elucidate viral and host factors in the pathogenesis of severe and fatal infections.
Acknowledgments. Contents of this article have been presented in conferences at the ESE Hospital Santa Monica, Dosquebradas,
Risaralda, Colombia, March 6, 2020; Universidad Tecnologica de Pereira, Risaralda, Colombia, Symposium on Neglected Tropical
Diseases, February 1, 2020, and Fundación Universitaria Autónoma de las Américas, Pereira, Risaralda, Colombia, February 20, 2020.
Author Contributions. AJRM and JACO formulated the research questions, designed the study, developed the preliminary search
strategy, and drafted the manuscript. EGO, RV, YHR refined the search strategy by conducting iterative database queries and
incorporating new search terms. EGO, RV, YHR, and AJRM searched and collected the articles. JACO, AJRM, and DKBA conducted
the quality assessment. All authors critically reviewed the manuscript for relevant intellectual content. All authors have read and
approved the final version of the manuscript.
Conflicts of interest. All authors report no potential conflicts. All authors have submitted the ICMJE Form for Disclosure of Potential.
Funding Source. Universidad Tecnológica de Pereira. Latin American Network of Coronavirus Disease 2019-COVID-19 Research
(LANCOVID-19) (www.lancovid.org). Study sponsors had no role in the study design, in the collection, analysis and interpretation of
data; in the writing of the manuscript; and in the decision to submit the manuscript for publication.
Ethical Approval. Approval was not required.
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15
Figure 1. Study selection and characteristics.
16
Table 1. Characteristics of the included studies on COVID-19, 2020. All patients confirmed by real-time RT-PCR. 1
2
Author Journal Date (MM/DD) Country Study type N Quality score* Reference
WMCHHHPNCI Comission Report 01/20 China Cross-sectional 136 12 [64]
Chaolin et al. Lancet 01/24 China Cross-sectional 41 19 [5]
Li et al. NEJM 01/29 China Cross-sectional 425 19 [11]
Chen et al. Lancet 01/30 China Cross-sectional 99 19 [4]
Chung et al. Radiology 02/04 China Cross-sectional 21 12 [65]
Chen et al. Chin J Tuberc Respir Dis 02/06 China Cross-sectional 29 12 [66]
Wang et al. JAMA 02/07 China Cross-sectional 138 19 [67]
Kui et al. Chin Med J 02/07 China Cross-sectional 137 12 [68]
Chang et al. JAMA 02/07 China Cross-sectional 13 14 [69]
To et al. Clin Infect Dis 02/12 China Cross-sectional 12 14 [70]
COVID-19 team Australia Team Report 02/12 Australia Cross-sectional 15 12 [71]
Yueying et al. Eur Radiol 02/13 China Cross-sectional 63 14 [72]
Li et al. Preprint Lancet 02/13 China Case series 24 14 [73]
Feng et al. Radiology 02/13 China Case series 21 12 [74]
Liang et al. Lancet Oncology 02/14 China Cross-sectional 1590 17 [41]
Zhang et al. Chin J Tuberc Respir Dis 02/15 China Case series 9 12 [40]
Feng et al. Chin J Pediatr 02/17 China Case series 15 12 [75]
Wang et al. Chin J Pediatr 02/17 China Cross-sectional 34 12 [76]
Xiaobo et al. Lancet Respir Med 02/21 China Cross-sectional 52 17 [52]
WMCHHHPNCI, Wuhan Municipal Commission of Health and Health on Pneumonia of New Coronavirus Infection. MM/DD, Month, Day. *Quality score ranged, 0-20. Based on the Appraisal Tool for Cross-Sectional Studies, AXIS.[36] 3
4
17
5
Table 2. Demographical characteristics, ICU, and comorbidities of the study subjects. 6
7
N (%)
Author Date
(MM/DD) N Mean Age
(y-old) Age Range Sex (Male) N at ICU Comorbidities Diabetes Hypertension Cardiovascular
disease
Chronic obstructive pulmonary
disease Malignancies Chronic liver
disease Reference
WMCHHHPNCI 01/20 136 - 25-89 66 - - - - - - - - [64]
Chaolin et al. 01/24 41 49 41-58 30 13 (31.7) 13 (31.7) 8 (19.5) 6 (14.6) 6 (14.6) 1 (2.4) 1 (2.4) 1 (2.4) [5]
Li et al. 01/29 425 56 26-82 240 - - - - - - - - [11]
Chen et al. 01/30 99 55.5 21-82 67 23 (23.2) 50 (50.5) 12 (12.1) - 40 (40.4) 1 (1.0) 1 (1.0) - [4]
Chung et al. 02/04 21 51 29-77 13 - - - - - - - - [65]
Chen et al. 02/06 29 56 26-79 21 - 16 (55.2) 5 (17.2) 8 (27.6) - - 1 (3.4) 2 (6.9) [66]
Wang et al. 02/07 138 56 42-68 75 36 (26.1) 64 (46.4) 14 (10.1) 43 (31.2) 20 (14.5) 4 (2.9) 10 (7.2) 4 (2.9) [67]
Kui et al. 02/07 137 57 20-83 61 - 27 (19.7) 14 (10.2) 13 (9.5) 10 (7.3) 2 (1.5) 2 (1.5) - [68]
Chang et al. 02/07 13 34 34-48 10 - - - - - - - - [69]
To et al. 02/12 12 62.5 37-75 7 - - - - - - - - [70]
COVID-19 team Australia 02/12 15 43 8-66 9 1 (6.7) - - - - - - - [71]
Yueying et al. 02/13 63 - 15.2 - 44.9 33 - - - - - - - - [72]
Li et al. 02/13 24 43 12 - 84 8 - - - - - - - - [73]
Feng et al. 02/13 21 40.9 25-63 6 - - - - - - - - [74]
Liang et al. 02/14 1590 - - 911 130 (8.2) 18 (1.1) 2 (0.1) 2 (0.1) - 1 (0.06) - - [41]
Zhang et al. 02/15 9 36 15-49 5 - 1 (11.1) 1 (11.1) - - - - - [40]
Feng et al. 02/17 15 - 4 - 14 5 - - - - - - - - [75]
Wang et al. 02/17 34 8 - 14 - - - - - - - - [76]
Xiaobo et al. 02/21 52 59.7 33.6-85.8 35 - 21 (40.4) 9 (17.3) - 5 (9.6) 4 (7.7) 2 (3.8) - [52]
WMCHHHPNCI, Wuhan Municipal Commission of Health and Health on Pneumonia of New Coronavirus Infection. MM/DD, Month, Day. ICU, intensive care unit. y-old, years old. -, Not available, not reported. 8
9
10
11
12
13
14
18
Table 3. Clinical characteristics of the study subjects. 15
16
N (%)
Author Date
(MM/DD) N Fever Cough Sore Throat Myalgia or
fatigue Sputum
production Headache Haemoptisis Diarrhoea Dyspnoea Reference
WMCHHHPNCI 01/20 136 136 (100.0) 136 (100.0) - - - - - - 136 (100.0) [64]
Chaolin et al. 01/24 41 40 (97.6) 31 (75.6) 0 (0.0) 18 (43.9) 11 (26.8) 3 (7.3) 2 (4.9) 1 (2.4) 22 (53.7) [5]
Li et al. 01/29 425 - - - - - - - - - [11]
Chen et al. 01/30 99 82 (82.8) 81 (81.8) 5 (5.1) 11 (11.1) - 8 (8.1) - 2 (2.0) 31 (31.3) [4]
Chung et al. 02/04 21 14 (66.7) 9 (42.9) - 6 (28.6) - 3 (14.3) - - - [65]
Chen et al. 02/06 29 28 (96.6) 21 (72.4) - 12 (41.4) 21 (72.4) 2 (6.9) - 4 (13.8) 17 (58.6) [66]
Wang et al. 02/07 138 136 (98.6) 82 (59.4) 24 (17.4) 138 (100.0) 37 (26.8) 9 (6.5) - 14 (10.1) 43 (31.2) [67]
Kui et al. 02/07 137 112 (81.8) 66 (48.2) - 44 (32.1) 6 (4.4) 13 (9.5) 7 (5.1) 11 (8.0) 26 (19.0) [68]
Chang et al. 02/07 13 12 (92.3) 6 (46.2) - 3 (23.1) 2 (15.4) 3 (23.1) - 1 (7.7) - [69]
To et al. 02/12 12 - - - - - - - - - [70]
COVID-19 team Australia 02/12 15 14 (93.3) 11 (73.3) - - - - - - - [71]
Yueying et al. 02/13 63 - - - - - - - - - [72]
Li et al. 02/13 24 19 (79.2) 6 (25.0) - 6 (25.0) - 4 (16.7) - - 2 (8.3) [73]
Feng et al. 02/13 21 18 (85.7) 12 (57.1) 4 (19.0) 11 (52.4) 6 (28.6) - - - - [74]
Liang et al. 02/14 1590 - - - - - - - - - [41]
Zhang et al. 02/15 9 8 (88.9) 5 (55.6) 4 (44.4) 4 (44.4) - - - - - [40]
Feng et al. 02/17 15 5 (33.3) 1 (6.7) - - - - - - - [75]
Wang et al. 02/17 34 17 (50.0) 13 (38.2) - - - - - - - [76]
Xiaobo et al. 02/21 52 51 (98.1) 40 (76.9) - 6 (76.9) - 3 (11.5) - - 33 (63.5) [52]
WMCHHHPNCI, Wuhan Municipal Commission of Health and Health on Pneumonia of New Coronavirus Infection. MM/DD, Month, Day. -, Not available, not reported. 17
18
19
20
21
22
23
19
24
Table 4. Laboratory characteristics of the study subjects. 25
26
N (%)
Author Date
(MM/DD) N Leucocytosis Leukopenia Lymphopenia High AST
High Creatinine
High Creatine kinase
High LDH
High Troponin I, >99th
perc Anemia Decreased Albumin High ALT
High Bilirubin
Erythrocyte sedimentation rate elevated
C-reactive protein, high Serum ferritin Reference
WMCHHHPNCI 01/20 136 - - - - - - - - - - - - - - - [64]
Chaolin et al. 01/24 41
12 (29.3) 10 (24.4) 26 (63.4) 15
(36.6) 4 (9.8) 13 (31.7)
29 (70.7)
5 (12.2) - - - - - - - [5]
Li et al. 01/29 425 - - - - - - - - - - - - - - - [11]
Chen et al. 01/30 99
24 (24.2) 9 (9.1) 35 (35.4) 35
(35.4) 3 (3.0) 13 (13.1)
75 (75.8)
- 50 (50.5) 97 (98.0) 28 (28.3) 18 (18.2) 84 (84.8) 63 (63.6) 62 (62.6) [4]
Chung et al. 02/04 21 - - - - - - - - - - - - - - - [65]
Chen et al. 02/06 29
6 (20.7) 6 (20.7) 20 (69.0) 7 (24.1) 2 (6.9) - 20
(69.0) - -
15 (51.7) 5 (17.2) 1 (3.4) - 27 (93.1) - [66]
Wang et al. 02/07 138
0 (0.0) 0 (0.0) 97 (70.3) - - - 55
(39.9) - - - - - -
- - [67]
Kui et al. 02/07 137 26 (19.0) 51 (37.2) 99 (72.3) - - - - - - - - - - 115 (83.9) - [68]
Chang et al. 02/07 13 - - - - - - - - - - - - - - - [69]
To et al. 02/12 12 - - - - - - - - - - - - - - - [70]
COVID-19 team Australia
02/12 15 - - - - - - - - - - - - - - - [71]
Yueying et al. 02/13 63 - - - - - - - - - - - - - - - [72]
Li et al. 02/13 24 - 5 (20.8) 2 (8.3) - - - - - - - - - 6 (25.0) 12 (50.0) - [73]
Feng et al. 02/13 21 - - - - - - - - - - - - - - - [74]
Liang et al. 02/14 1590 - - - - - - - - - - - - - - - [41]
Zhang et al. 02/15 9 1 (11.1) - 2 (22.2) - - - - - - - - - - 5 (55.6) - [40]
Feng et al. 02/17 15 - 8 (53.3) - - - - - - - - - - - - - [75]
Wang et al. 02/17 34
5 (14.7) 1 (2.9) 1 (2.9) - - - 10
(29.4) - - - - -
5 (14.7) 1 (2.9) - [76]
Xiaobo et al. 02/21 52 - - - - - - - - - - - - - - - [52]
WMCHHHPNCI, Wuhan Municipal Commission of Health and Health on Pneumonia of New Coronavirus Infection. MM/DD, Month, Day. LDH, Lactate dehydrogenase. AST, Aspartate transaminase. ALT, Alanine transaminase. -, Not available, not reported. 27
20
28
29
30
31
Table 5. Imaging and complications of the study subjects. 32
33
N (%)
Imaging Complications
Author Date
(MM/DD) N
Chest Ray Unilateral Pneumonia
Chest Ray Bilateral
Pneumonia
Ground-glass
opacity
Acute respiratory
distress syndrome RNAaemia
Acute cardiac injury
Acute kidney injury
Secondary
infection Shock Hospitalization Discharge Death Reference
WMCHHHPNCI 01/20 136 - - - - - - - - - - - 1 (0.7) [64]
Chaolin et al. 01/24 41 - 40 (97.6) 40 (97.6) 12 (29.3) 6 (14.6) 5 (12.2) 3 (7.3) 4 (9.8) 3 (7.3) 7 (17.1) 28 (68.3) 6 (14.6) [5]
Li et al. 01/29 425 - - - - 425 (100.0) - - - - - - - [11]
Chen et al. 01/30 99 25 (25.3) 74 (74.7) 14 (14.1) 17 (17.2) 99 (100.0) - 3 (3.0) - 4 (4.0) 57 (57.6) 31 (31.3) 11 (11.1) [4]
Chung et al. 02/04 21 2 (1.5) 16 (11.8) 18 (13.2) - 21 (15.4) - - - - 21 (15.4) - - [65]
Chen et al. 02/06 29 - - 29 (100.0) - 29 (100.0) - - - - 27 (93.1) - 2 (6.9) [66]
Wang et al. 02/07 138 0 (0.0) 138 (100.0) 138 (100.0) 27 (19.6) 138 (100.0) 10 (7.2) 5 (3.6) - 12 (8.7) 138 (100.0) 47 (34.1) 6 (4.3) [67]
Kui et al. 02/07 137 - 36 (26.3) 55 (40.1) - 137 (100.0) - - - - 77 (56.6) 44 (32.4) 16 (11.8) [68]
Chang et al. 02/07 13 1 (7.7) - 6 (46.2) - 13 (100.0) - - - - 12 (92.3) 1 (7.7) - [69]
To et al. 02/12 12 - - - - 12 (100.0) - - - - 12 (100.0) - - [70]
COVID-19 team Australia 02/12 15 - - - - 15 (100.0) - - - - 11 (73.3) - - [71]
Yueying et al. 02/13 63 - 38 (60.3) 14 (22.2) - 63 (100.0) - - - - - - - [72]
Li et al. 02/13 24 - - - - 24 (100.0) - - - - - - - [73]
Feng et al. 02/13 21 18 (85.7) - - - 21 (100.0) - - - - 21 (100.0) - - [74]
Liang et al. 02/14 1590 - - - - - - - - 1590 (100.0) - - [41]
Zhang et al. 02/15 9 2 (22.2) 5 (55.6) 7 (77.8) - 9 (100.0) - - - - 9 (100.0) - - [40]
Feng et al. 02/17 15 4 (26.7) 8 (53.3) - - 15 (100.0) - - - - - 15 (100.0) - [75]
Wang et al. 02/17 34 - 34 (100.0) 34 (100.0) - 34 (100.0) - - - - 34 (100.0) 34 (100.0) - [76]
Xiaobo et al. 02/21 52 - - - 35 (67.3) - 12 (23.1) 15 (28.8) 2 (3.8) - 52 (100.0) - 32 (61.5) [52]
WMCHHHPNCI, Wuhan Municipal Commission of Health and Health on Pneumonia of New Coronavirus Infection. MM/DD, Month, Day. ICU, intensive care unit. y-old, years old. AST, Aspartate transaminase. ALT, Alanine transaminase. -, Not available, not reported. 34
21
Table 6. Meta-analysis outcomes (random-effects model)*. 35
Variable Number of
Studies Mean (y-old) / Prevalence (%) 95%CI n Q† I2 ‡ t2 § P
Age 18 51.97 46.06-57.89 2626 1193.28 98.56 145.687 <0.001
Male 22 55.9 51.6-60.1 2874 61.98 66.12 0.005 <0.001
ICU 6 20.3 10.0-30.6 1883 49.49 89.89 0.013 <0.001
Comorbidities 7 36.8 24.7-48.9 505 47.75 87.44 0.022 <0.001
Hypertension 5 18.6 8.1-29.0 363 23.989 83.33 0.011 <0.001
Cardiovascular disease 6 14.4 5.7-23.1 485 45.29 88.96 0.01 <0.001
Diabetes 8 11.9 9.1-14.6 523 4.065 0.00 0.00 0.772
Chronic obstructive pulmonary disease 6 1.8 0.6-3.0 485 4.413 0.00 0.00 0.492
Malignancies 6 2.5 0.7-4.2 496 7.59 34.16 0.00 0.180
Chronic liver disease 3 3.0 0.7-5.4 208 0.744 0.00 0.00 0.689
Clinical manifestations
Fever 15 88.7 84.5-92.9 784 128.73 89.12 0.04 <0.001
Adult 13 92.8 89.4-96.2 735 68.25 82.42 0.002 <0.001
Children 2 43.9 28.2-59.6 49 1.25 20.2 0.003 0.263
Cough 15 57.6 40.8-74.4 784 657.76 97.87 0.102 <0.001
Adult 13 63.4 48.0-78.8 735 413.05 97.09 0.072 <0.001
Children 2 22.0 0.0-52.9 49 8.983 88.87 0.044 0.003
Dyspnea 8 45.6 10.9-80.4 656 1346.86 99.48 0.248 <0.001
Myalgia or fatigue 11 29.4 19.8-39.0 446 46.53 80.66 0.017 <0.001
Sputum production 6 28.5 10.8-46.3 379 94.94 94.73 0.044 <0.001
Sore throat 5 11.0 2.8-19.2 308 28.24 85.39 0.006 <0.001
Headache 9 8.0 5.7-10.2 554 5.048 0.00 0.00 0.752
Diarrhea 6 6.1 2.4-9.7 457 13.19 62.11 0.001 0.022
Laboratory findings
Decreased Albumin 2 75.8 30.5-100.0 128 24.29 95.88 0.103 <0.001
High C-reactive protein 6 58.3 21.8-94.7 332 472.34 98.94 0.200 <0.001
High LDH 5 57.0 38.0-76.0 341 54.03 92.59 0.043 <0.001
Lymphopenia 8 43.1 18.9-67.3 511 349.18 97.99 0.117 <0.001
High Erythrocyte sedimentation rate 3 41.8 0.0-92.8 157 118.55 98.31 0.199 <0.001
High AST 3 33.3 26.3-40.4 169 1.7 0.00 0.00 0.427
High ALT 2 24.1 13.5-34.6 128 1.749 42.84 0.003 0.186
High Creatinine Kinase 2 21.3 3.2-39.4 140 5.36 81.36 0.014 0.021
Leukopenia 8 18.7 8.5-28.8 517 126.80 94.48 0.018 <0.001
Leukocytosis 7 16.8 5.5-28.0 487 87.47 93.14 0.019 <0.001
High Bilirubin 2 10.7 0.0-25.1 128 8.19 87.79 0.01 0.004
High Creatinine 3 4.5 1.0-8.0 169 2.23 10.17 0.00 0.328
Chest X-Ray Pneumonia Compromise
Unilateral 7 25.0 5.2-44.8 316 165.31 96.37 0.065 <0.001
Bilateral 9 72.9 58.6-87.1 557 463.64 98.28 0.042 <0.001
Adult 7 70.7 50.4-91.0 508 451.59 98.67 0.070 <0.001
Children 2 77.7 33.5-100.0 49 12.04 91.69 0.094 <0.001
Image findings
Ground-glass opacity 10 68.5 51.8-85.2 584 992.3 99.09 0.068 <0.001
Complications
RNAemia 18 96.8 94.9-98.7 1096 241.19 92.95 0.001 <0.001
Adult 16 96.6 94.6-98.6 1047 240.59 93.77 0.001 <0.001
Children 2 98.3 94.7-100.0 49 0.125 0.00 0.00 0.723
Acute respiratory distress syndrome 4 32.8 13.7-51.8 330 49.49 93.93 0.035 <0.001
Acute cardiac injury 3 13.0 4.1-21.9 231 6.72 70.22 0.004 0.035
Acute kidney injury 4 7.9 1.8-14.0 330 16.5 81.85 0.003 <0.001
Shock 3 6.2 3.1-9.3 278 2.34 14.67 0.00 0.310
Secondary infections 2 5.6 0.3-10.9 93 1.22 18.16 0.00 0.269
Hospitalization 15 87.9 84.2-91.6 2211 390.76 96.42 0.004 <0.001
Outcome
Discharged 7 52.9 23.9-81.8 477 548.77 98.91 0.15 <0.001
Death 7 13.9 6.2-21.5 632 107.17 91.4 0.009 <0.001 * 95% CI = 95% confidence interval; ICU, intensive care unit. y-old, years old. AST, Aspartate transaminase. ALT, Alanine transaminase. 36 † Cochran’s Q statistic for heterogeneity. 37 ‡ I2 index for the degree of heterogeneity. 38 § Tau-squared measure of heterogeneity. 39
40
22
Table 7. Summary of the case report findings.* 41
Variables N (126) % Variables N (126) %
Age (y-old) (mean, SD) (n=118) 47.9 22.2 Images
Sex (Male/Female) (n=71) 49 69.01 Ground-glass opacity at chest X-ray 58 46.0
ICU (Yes) 11 8.7 Chest X-Ray Bilateral Pneumonia 50 39.7
Comorbidities Chest X-Ray Unilateral Pneumonia 13 10.3
Hypertension 13 10.3 Complications
Chronic liver disease 5 4.0 RNAaemia 126 100.0
Cardiovascular disease 3 2.4 Acute respiratory distress syndrome 9 7.1
Chronic obstructive pulmonary disease 2 1.6 Secondary infection 2 1.6
Malignancy or cancer 1 0.8 Acute kidney injury 1 0.8
Clinical features Shock 1 0.8
Fever 97 77.0 Hospitalization 94 74.6
Cough 70 55.6 Outcomes
Myalgia or fatigue 39 31.0 Discharge 48 38.1
Dyspnoea 27 21.4 Death 20 15.9
Sputum production 16 12.7
Sore Throat 13 10.3 Countries of the case report articles (39)
Diarrhoea 8 6.3 China 25 64.1
Headache 7 5.6 South Korea 4 10.3
Haemoptisis 1 0.8 Australia 1 2.6
Laboratory findings Canada 1 2.6
Lymphopenia 30 23.8 France 1 2.6
High C-reactive protein 28 22.2 Germany 1 2.6
High AST 10 7.9 Japan 1 2.6
Leukopenia 9 7.1 Nepal 1 2.6
High ALT 9 7.1 Taiwan 1 2.6
High LDH 8 6.3 Thailand 1 2.6
High Erythrocyte sedimentation rate 6 4.8 United States of America 1 2.6
Leukocytosis 4 3.2 Vietnam 1 2.6
Anemia 4 3.2 Countries of the cases reported (n=126)
Decreased Albumin 3 2.4 China 101 80.2
High Creatinine 2 1.6 South Korea 6 4.8
High Creatine kinase 2 1.6 Germany 5 4.0
High Bilirubin 1 0.8 France 3 2.4
Australia 2 1.6
Taiwan 2 1.6
Vietnam 2 1.6
Canada 1 0.8
Japan 1 0.8
Nepal 1 0.8
Thailand 1 0.8
United States of America 1 0.8
*The list of case reports is available at Table S1—supplemental materials. 42
43
44
23
Supplemental Materials. 45
Figure S1. Funnel-plot for the Standard Error by Logit Event rate to assess for publication bias. 46
47
48
49
24
Figure S2. Pool prevalences forest plots of findings described in Table 2. 50
51
25
Table S1. Case reports included in the review. 52
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